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Directory entires that have specified Svalbard as one of the geographic regions for the project/activity and are included in the AMAP, ENVINET, SAON and SEARCH directories. Note that the list of regions is not hierarchical, and there is no relation between regions (e.g. a record tagged with Nunavut may not be tagged with Canada). To see the full list of regions, see the regions list. To browse the catalog based on the originating country (leady party), see the list of countries.
It is also possible to browse and query the full list of projects.
MOSJ (Environmental Monitoring of Svalbard and Jan Mayen) is an environmental monitoring system and part of the Government’s environmental monitoring in Norway. An important function is to provide a basis for seeing whether the political targets set for the development of the environment in the North are being attained
National Environmental Monitoring in Sweden in the "Air" programme. The objective of the project is to follow climate-changing gases and particles and which effects they could have on the climate of earth. To understand and assess the human effect on the climate, regionally and globally, the atmospheric aerosols and greenhouse gases are monitored. The project aims follow: (i) detecting long-term trends in the carbon dioxide level, as well as trends in the amount or composition of aerosols in the background atmosphere; (ii) provide a basis to study the processes that control the aerosol life cycle from their formation through aging and transformation, until being removed from the atmosphere; (iii) provide a basis to study the processes (sources, sinks, and transport pathways) that control the level of carbon dioxide in the atmosphere; (iv) contribute to the global network of stations that perform continous measurements of atmospheric particles and trace gases to determine their effect on the earths radiation balance and interaction with clouds and climate.
At the Zeppelin Station on Svalbard, Stockholm University, Department of Environmental Science and Analytical Chemistry (ACES) measures trends in atmospheric carbon dioxide in background atmosphere (Table 4, #1.6, Table 5, ##3–4). In collaboration with NOAA/CMDL in Boulder, USA, air is regularly sampled in flasks for analysis of CO2, CH4, CO, 13CO2, H2, N2O, SF6, and 18O in CO2. At the top of the micrometeorological tower (102 m) at Norunda north of Uppsala, carbon dioxide and methane concentrations are also measured (Fig. 2, Table 5, #5). Other sites for CO2 measurements are the flux sites described below. Air samples are taken at 10 sites in northern Sweden for analysis of SO2, NO2, and surface-near ozone (Fig. 2, Table 4, #1.2) in the air- and precipitation chemistry network. At the Zeppelin Station on Svalbard, Stockholm University, Department of Environmental Science and Analytical Chemistry (ACES) also measures the amount and composition of aerosols in the background atmosphere. Measurements include particle concentration and size distribution, light absorption and scattering, and cloud residual properties (cloud residuals are the particles which took part in cloud droplet or ice crystal formation)
Arctic study of trophospheric aerosol, clouds and radiation
INTERMAGNET is global network of observatories, monitoring the Earth's magnetic field
The prime objectives of IMAGE are to study auroral electrojets and moving two-dimensional current systems.
Weather forecasting Main gaps: These observations are operational observations of METNO
This station is one of many international stations in Ny-Aalesund, Svalbard. Traditionally research has focussed on the ecology of barnacle geese. The research now includes monitoring of plant production, vegetation change, insect phenology, arctic terns, snowbuntings, barnacle geese, reindeer and arctic foxes. Regular guests are Dutch institutions for marine research like IMARES and NIOZ and researchers from NIOO and VU.
The main objective is to study adaptations to climate warming and understanding dynamics of animal and plant populations.
Fluvial transport, its dynamics and structure, constitute a good indicator of the condition of the natural environment in various climatic zones. Analysis of fluvial transport components allows for precise determination of the rate and directions of transformations of geosystems of any importance. In the polar zone, very sensitive to global changes, it seems expedient to identify the mechanisms and structure of fluvial transport, particularly in the conditions of the observed glacier retreat, the main alimentation source of proglacial rivers. Studies carried out in the zone revealed difficulties in determination of fluvial transport structure, particularly the actual bedload of gravel-bed rivers based on direct measurements, resulting from: short measurement series, lack of standardization of research methods and measurement equipment, and strategy of selection of study objects and sampling. The research project presented concerns determination of mechanisms of fluvial transport and sediment supply to Arctic gravel-bed river channels. The mechanisms reflect the processes of adaptation of proglacial rivers of the Arctic zone to changing environmental conditions, and indicate the dominant directions of transformations of paraglacial geosystems of various importance. For studies on Arctic geosystems, the region of the south Bellsund (SW Spitsbergen) was selected due to extensive knowledge on its hydro-meteorological and glacial-geomorphological conditions, and long-term measurement series carried out by the research station of the MCSU, among others within the framework of the international monitoring network: SEDIBUD (IAG) and Small-CATCHMENT program. For detailed studies, rivers with various hydrological regimes were selected, functioning at the forefield of the Scott and Renard Glaciers. The Scott River glacial catchment and glacier-free catchments of the Reindeer Stream and the Wydrzyca Stream (with a snow-permafrost hydrological regime) meet the selection criteria for representative test catchments analyzed for the following programs: SEDIFLUX, SEDIBUD, and POP.
Continuous measurements of greenhouse gases and particles to monitor changes in the atmosphere. The programme is operated by Norwegian Institute of Air Research (NILU) on behalf of Norwegian Environment Agency. The Zeppelin Observatory is a major contributor of data on a global as well as a regional scale.The programme is decribed in the link.
The main objective is to quantify the levels of air pollution in the artctic, and to document any changes in the exposures. It includes the necessary components to address impacts on ecosystems, human health, materials and climate change.
Local monitoring, Barentsburg: regular sampling, twice a year
Zooplankton make essential links between producers and predators in marine ecosystems, so mediating in the CO2 exchange between atmosphere and ocean They can be indicators of climate variability, and changes in zooplankton species distribution and abundance may have cascading effects on food webs. West Spitsbergen Current is the main pathway of transport of Atlantic waters and biota into the Arctic Ocean and the Arctic shelf seas. West Spitsbergen Shelf coastal and fjordic waters, therefore, are natural experimental areas to study mechanisms by which the Atlantic and Arctic marine ecosystem interact, and to observe environmental changes caused by variability in climate. The main objectives of the zooplankton monitoring are: a) to study patterns and variability in composition and abundance in zooplankton of the West Spitsbergen Current and the West Spitsbergen fjords and coastal waters; b) to find out environmental factors responsible for the observed patterns and variability in zooplankton, and to understand possible relations between zooplankton and their environment on different space and time scales; c) to observe and monitor the variability in zooplankton in relation to local and global climate changes.
Project aims indicate of changes of main terrestrial cryosphere components – glaciers and permafrost. Research on glaciers assumes both to inspect recent changes (mass balance, geometry, thermal structure and widely understood dynamics) and to reconstruct past events (especially in base on subaqual records in the marine-part forefields of the tide-water glaciers). Selected research results are part of the World Glacier Monitoring Service (WGMS). The most widely studied are Waldemar Glacier, Irene Glacier and Elise Glacier. Several research aspects, such as geometry of glaciers are investigated for more than 30 years, since first NCU Polar Expedition in 1975. Permafrost investigations are focused on the depth of the summer active layer thawing and thermal properties of it. Selected results constitutes a part of Circumpolar Active Layer Monitoring (CALM) programme.
The study of the OH layer between about 80 to 95 km altitude reveals important infomation about the mesopause region. An interesting information, which can be drawn from the relaxation of chemically excited OH molecules, is the rotational temperature of this layer, which forms the boundary between mesosphere and thermosphere. Under certain circumstances, the rotational temperature of the OH molecules can be related to the ambient temperature of the air at the mesopause region. The OH molecules are formed by the reaction of O3 and H2, which leaves the OH molecules at a highly excited vibrational state. The course of the deexcitation is still subject of discussion and will be studied using a FTIR spectrometer, which is able to observe the transistions reching from the higlhy excited state to the ground state of the OH molecule. The ground state of the OH molecule can be observed by LIDAR. A method to do this will be developed in a project at the Universität Bremen in cooperation with the AWI Potsdam.
INGV operates in the Arctic region with observational activities in Svalbard, near the area of Ny-Ålesund, where the Institute has installed three stations to monitor ionospheric scintillation, currently in operation. In Svalbard, the PEGASO (Polar Explorer for Geomagnetic And other Scientific Observations) project has performed several stratospheric balloon launches (Pathfinders) with the aim of studying the Earth's magnetic field in an area with poor coverage measurements and of studying the possible trajectories of circumpolar winds at high altitudes. At the Greenland Base of Thule, INGV in collaboration with CNR, DMI (Danish Meteorological Institute), University of Rome La Sapienza and ENEA, carries out spectrometric observations for the analysis of stratospheric chemistry and mesosphere to monitor the ozone layer. In cooperation with In addition, an upper atmosphere permanent observatory for magnetosphere and Ionosphere sounding, including Auroras, and other geophysical processes is operated in Greenland, Zackemberg station in cooperation with Danish scientists. INGV is currently involved in the coordination of two European initiatives: a) EMSO (European Multidisciplinary seafloor Observatory) a European research infrastructure of ESFRI (European Strategy Forum on Research Infrastructures), which counts to establish a multi-parametric permanent network in the surrounding European seas, including the Arctic area. The project began in April 2008 with the participation of 11 European countries; b) EUROANDRILL, created under the aegis of the European Science Foundation, aims to drill key areas of polar areas to study past and future climate. The project involves the involvement of 10 European and 3 extra-European countries. The Institute is also active in other projects in the Arctic, in particular actively participates in the seismic network GLISN, developed from the existing stations in and around Greenland.
Research station in Ny-Ålesund, Svalbard
Our objective in present SAON meeting was to know more about SAON activities and plannings to coordinate and promote guidelines criteria for observations in the ARctic Present Spain Research in Arctic is performed mainly for universities and scientific institutions , down the responsability of the Science Department with the support of several national institutions including the Defense Department and Foreign Affairs Institutions are coordinated by the National Polar Committee. The National Scientific Program finance the activities in the polar zones Although our main scientific activities are in Antarctica the activity of Spain in Arctic is rapidly increasing following the fact that Arctic research is a priority task in our Science Program At present we have detected 16 scientific groups working activelly in the differnts fields of Arctic topics (glaciology, meteorology, permafrost, high atmosphere, ecology, physical oceanography, marine geology and biology) These activities are mainly performed in cooperation with Arctic countries Institutions via institutional or researchers contacts About our media to work in Arctic ocean Spain has at present two multiporposes oceanographic research ships In the last years our Ocanographic ship Hesperides has developed two campaigns in The area of Greenland and Svalvars Island in the fields of marine Geology , marine biology and physical oceanography For next summer Hesperides will perform a third oceanographic campaign close to the Atlantic coast of Greenland Other national institutions have been working in marine biology campaigns including fisheries stock evolution Spain has a National Centre of Polar Data were all researchers must enter their raw data gathered in the polar campaigns We considerer , at present , our interest to cooperate inside SAON board, considering that besides other possible cooperation to SAON tasks could be a cooperation with our Polar Data Centre
monitoring of thermal and humidity parameters of arctic atmospheric boundary layer in horizontal and vertical profile covering glaciated area, non-glaciated area and mountain peak
University of Silesia in close cooperation with the Institute of Geophysics, Polosh Academy of Sciences (PAS) has developed and maintain monitoring of glaciers in SW Spitsbergen, Svalbard. Monitoring network of land ice masses in Southern Spitsbergen is aimed to study the response of tidewater glaciers to climate warming, with focus on mass loss due to calving. Seasonal and interannual changes in glacier flow velocity, fluctuation of terminus position and calving rate are studied for better understanding of ice berg calving. The target glacier Hansbreen has a comprehensive ground observing system (Figure 21). It consists of mass balance stakes, automatic weather stations (AWS), time lapse GPS survey of velocity at stake T4, two time lapse cameras, automatic laser ranger and panoramic radar for measurements of ice cliff fluctuations. Moreover, mass balance, including snow cover studies are conducted every year since 1989. In some years high frequency ground penetrating radar is used for snow thickness measurements along the same profiles on the glacier. Satellite remote sensing is used for extraction of data on glacier flow velocity and fluctuation of termini and calculation of mass loss by calving. Up-to-dated inventory of glaciers in Southern Spitsbergen has been done by remote sensing methods (Figure 23). Studies are conducted in cooperation with Spanish, Norwegian and Italian partners. Cooperation with Institute of Oceanology, PAS (since 2010) is developed to monitor sea water parameters for studies of sea water - ice cliff interaction. Main gaps: Gaps in series of observations due to failures of equipment, lack of power supply or damage by polar bears. Long term tide and wave record required. More tidewater glaciers advisable with monitoring of flow velocity by GPS as ground truth data for calibration of remote sensing survey.